Measurement device and measurement method

ABSTRACT

A measurement device includes a biosensor having a light-receiving part to receive measuring light from a region to be tested and configured to obtain a biometric output based on the measuring light, and a controller configured to determine whether or not to perform measurement of biological information based on the biometric output and a predetermined threshold. A measurement method includes obtaining a biometric output by a biosensor, and determining, by a controller, whether or not to perform measurement of biological information based on the biometric output and a predetermined threshold.

CROSS-REFERENCE TO RELATED APPLICATION

This application is a Continuation of U.S. patent application Ser. No.15/311,158 filed Nov. 14, 2016, which is the U.S. National Phase ofInternational Application No. PCT/JP2015/002707 filed May 28, 2015,which claims priority to and the benefit of Japanese Patent ApplicationNo. 2014-110248 filed May 28, 2014, the entire contents of which areincorporated herein by reference.

TECHNICAL FIELD

This disclosure relates to a measurement device and a measurementmethod.

BACKGROUND

A biological information measurement device that measures the biologicalinformation, such as pulses or the like, of the user has been known. Thebiological information is measured by various methods by using abiological information measurement device.

SUMMARY

According to one embodiment of the present disclosure, a measurementdevice includes, an ear canal connection, a shaft a biological sensorand a controller. The ear canal connection is configured to be insertedinto an ear canal. The shaft is extending from the ear canal connectionalong an insertion direction. The biological sensor is configured to beturnable about the shaft relative to the ear canal connection. Thecontroller is configured to measure biological information based on abiometric output obtained from the biological sensor.

According to one embodiment of the present disclosure, a measurementdevice includes a biosensor having a light-receiving part to receivemeasuring light from a region to be tested and configured to obtain abiometric output based on the measuring light, and a controllerconfigured to determine whether or not to perform measurement ofbiological information based on the biometric output and a predeterminedthreshold.

As described above, although a solution of this disclosure has beenexplained as devices, this disclosure can be realized as methodssubstantially corresponding to the devices, and it will be appreciatedthat the scope of this disclosure includes them.

For example, according to an embodiment of the present disclosure, ameasurement method includes obtaining a biometric output by a biosensor,and determining, by a controller, whether or not to perform measurementof biological information based on the biometric output and apredetermined threshold.

BRIEF DESCRIPTION OF THE DRAWINGS

In the accompanying drawings:

FIG. 1 is a functional block diagram of a measurement device accordingto one embodiment of this disclosure;

FIG. 2 is a diagram illustrating a cross-sectional schematicconfiguration of an insertion part according to one embodiment of thisdisclosure;

FIG. 3 is a diagram illustrating a state where the insertion part inFIG. 2 is inserted into an ear canal;

FIG. 4 is a flow chart illustrating an example of a process performed byan earphone controller illustrated in FIG. 1;

FIG. 5A and FIG. 5B are a diagram illustrating one example of the pulsewave data obtained by a biological sensor illustrated in FIG. 1; and

FIG. 6 is a functional block diagram of main parts of the measurementdevice in the case where a predetermined control for position adjustmentis performed by a mobile phone controller 220.

DETAILED DESCRIPTION

In the pulse measurement device, the measurement accuracy variesdepending on the positional relationship between the pulse wave sensorand the blood vessel located on a measurement point of the pulse wave.However, in the conventional pulse measurement device, in some cases,the biological information could not be measured accurately for adifficulty in adjusting the position of the pulse wave sensor.

The present embodiment has been conceived in light of the aboveconsiderations and provides a measurement device and a measurementmethod capable of improving the measurement accuracy of the biologicalinformation.

The following describes embodiments of this disclosure with reference tothe drawings.

FIG. 1 is a functional block diagram of main parts of the measurementdevice according to one embodiment of this disclosure. The measurementdevice according to this disclosure is realized by an earphone 100. Theearphone 100 includes an insertion part 110, an earphone controller 120,a storage 130, a communication interface 140 and a notification unit150. The earphone 100 measures the biological information by using abiological sensor 111 mounted on the insertion part 110 with theinsertion part 110 inserted to an ear canal of the user. When theearphone 100 according to this embodiment is used, the user may adjustthe position of the biological sensor 111 beforehand. After adjustingthe position once, the user does not need to adjust the position againunless the position of the biological sensor 111 is changed, forexample.

The biological information is any information that can be measured byusing the biological sensor 111 provided in the insertion part 110. Asone example, the following explanation is given assuming that theearphone 100 measures the pulse of the user in this embodiment.

When the user measures pulse, he/she wears the insertion part 110 inhis/her ear. FIG. 2 is a diagram illustrating a cross-sectionalschematic configuration of the insertion part 110 according to oneembodiment of this disclosure. In FIG. 2, the insertion part 110 isinserted into the user's ear canal to the left. The insertion part 110includes the biological sensor 111, a sensor disposing part 112, a soundguide tube 113 as a shaft, a vibration plate 114, a driving unit 115 andan ear canal connection 116.

The biological sensor 111 is a pulse wave sensor and obtains pulse wavedata, as a biometric output, from the user (living body). The biologicalsensor 111 includes a light-emitting element such as a LED (Lightemitting diode) or the like and a light-receiving element such as a PT(Phototransistor) or a PD (Photodiode) or the like, for example. Thebiological sensor 111 measures the pulse wave data by allowing thelight-emitting element to irradiate the measuring light to a region tobe tested in an ear canal of the user and allowing the light-receivingelement to receive the reflected light from the region to be tested. Inthe case of such measurement by the light, the biological sensor 111does not always have to be in contact with the ear canal.

The biological sensor 111 is disposed on the outer periphery of thecylindrical sensor disposing part 112. In the earphone 100 according tothis embodiment, the sensor disposing part 112 is disposed on the outerperiphery side of the sound guide tube 113. The sensor disposing part112 has a turn adjusting part 117 on the opposite side of the sideinserting to the ear canal.

A part of the sensor disposing part 112 except for the turn adjustingpart 117 is covered with the ear canal connection 116. The sensordisposing part 112 is configured to be turnable about the sound guidetube 113 relative to the sound guide tube 113 and the ear canalconnection 116. The sensor disposing part 112 may be configured to beturnable clockwise/counterclockwise 180 degrees, respectively. Thesensor disposing part 112 may include a lock mechanism with respect toeach predetermined rotating angle (e.g. 10 degrees) and be configured tobe turnable in stages. As illustrated in FIG. 3, for example, the usermay pinch the turn adjusting part 117 with his/her fingers to turn itwith the insertion part 110 inserted into his/her ear canal, therebyallowing the sensor disposing part 112 to be turned. As a result ofthis, the position of the biological sensor 111 disposed on the sensordisposing part 112 is changed. Thus, the region to be tested to whichthe biological sensor 111 irradiates the measuring light in the earcanal is changed. The user adjusts the position of the biological sensor111 by turning the biological sensor 111.

The sound guide tube 113 is cylindrical and extends along the directioninserting to the ear canal. The sound guide tube 113 serves as arotating shaft when the sensor disposing part 112 turns relative to theear canal connection 116. The sound guide tube 113 transmits the soundgenerated by the sound generator (speaker unit) configured with thevibration plate 114 and the driving unit 115 in the insertion directionof the ear canal connection 116 to the ear canal, that is, transmits thesound into the ear of the user. The driving unit 115 causes thevibration plate 114 to vibrate based on a sound signal of the soundgenerated by a mobile telephone 200 as a sound source device. Thevibration plate 114 vibrates based on the driving of the driving unit115 to reproduce sound. Driving of the driving unit 115 is controlled bythe earphone controller 120, for example.

The ear canal connection 116 covers a part of the insertion part 110 andcontacts the ear canal when the insertion part 110 is inserted into theear canal. The ear canal connection 116 is formed from a material thatallows the measuring light irradiated from the biological sensor 111 andthe reflected light from the region to be tested to transmit easily. Forexample, when the measuring light and the reflected light are infraredrays, the ear canal connection 116 may be formed from silicon.

With reference to FIG. 1 again, the earphone controller 120 is aprocessor that controls overall operation of the earphone 100. When theuser measures the biological information, the earphone controller 120measures pulse as the biological information based on the pulse wavedata obtained from the biological sensor 111.

When the user adjusts the position of the biological sensor 111, theearphone controller 120 performs a predetermined control. For example,the earphone controller 120 determines whether or not the pulse wavedata, which is the biometric output, is within the allowable range thatcan be used for measurement of the biological information. When theearphone controller 120 determines that the pulse wave data is notwithin the allowable range, it allows the notification unit 150 toindicate that the biological sensor 111 is needed to be turned. On theother hand, when the earphone controller 120 determines that the pulsewave data is within the allowable range, it adjusts the intensity of themeasuring light irradiated from the biological sensor 111 to the regionto be tested. The predetermined control performed by the earphonecontroller 120 when the user adjusts the position of the biologicalsensor 111 will be described in detail below with reference to FIG. 4.

The storage 130 can be configured with a semiconductor memory, amagnetic memory or the like, for example, and stores various kinds ofinformation and a program for operating the earphone 100, or the like.The storage 130 stores the information (threshold) relating to theallowable range that is a criterion for determining whether or not thepulse wave data obtained by the biological sensor 111 can be used forthe measurement of the biological information.

The communication interface 140 is connected to the sound source devicewired or wirelessly by Bluetooth® or the like to communicate with eachother. The sound source device can be any one of miscellaneous soundsource devices such as, for example, a mobile telephone, a mobile musicplayer, a laptop computer, a tablet terminator, a game machine, or thelike. In this specification, explanation is give on the assumption thatthe sound source device is a mobile telephone 200. The earphone 100transmits the biological information measured by the earphone controller120, for example, to the mobile telephone 200 via the communicationinterface 140. The earphone 100 receives the information relating to asound signal of the sound reproduced from the mobile telephone 200, forexample, via the communication interface 140.

The notification unit 150 notifies the user that the biological sensor111 is needed to be turned, based on the control by the earphonecontroller 120, by a visual method with images, characters, lightemission or the like, an auditory method such as sound or the like, or acombination thereof. In the case of notification by an auditory method,the notification unit 150 provides a notification by displaying imagesor characters on a display device configured with a liquid crystaldisplay, an organic EL display, an inorganic EL display or the like, forexample. The notification unit 150 may notify by light emission of alight-emitting element such as a LED or the like that is configuredseparately from the biological sensor 111, for example. In the case ofnotification by an auditory method, the notification unit 150 provides anotification by outputting alarm sound, sound guide, or the like, fromthe sound generator provided in the insertion part 110, for example. Itshould be noted that the notification provided by the notification unit150 is not limited to an auditory or visual notification, and thenotification may be provided in any method that can be recognized by theuser.

It should be noted that the earphone controller 120 may provide anotification by displaying images or characteristics on a display 260 ofthe mobile telephone 200 connected via the communication interface 140,for example. In this case, the earphone 100 does not need to include thenotification unit 150.

The mobile telephone 200 can be a smartphone, for example, and isconnected to the earphone 100. The mobile telephone 200 includes amobile telephone controller 220, a communication interface 240, adisplay 260 and an input interface 270.

The mobile telephone controller 220 is a processor that controls overalloperation of the mobile telephone 200. The mobile telephone controller220 allows the display 260 to display the biological informationmeasured by the earphone 100, for example. The mobile telephonecontroller 220 generates a sound signal of the sound reproduced from theinsertion part 110 of the earphone 100, for example.

The communication interface 240 is connected wired or wirelessly to theearphone 100 to communicate with each other. The mobile telephone 200receives the biological information measured by the earphone 100 via thecommunication interface 240, for example. The mobile telephone 200transmits the information relating to the sound signal of the soundreproduced from the insertion part 110 of the earphone 100 to theearphone 100 via the communication interface 240, for example.

The display 260 is a display device such as, for example, a liquidcrystal display, an organic EL display, an inorganic EL display, or thelike. The display 260 displays the biological information measured bythe earphone 100. The user can know his/her own biological informationby confirming the display on the display 260.

The input interface 270 accepts an operation input from the user, and isconfigured with operation buttons (operation keys), for example. Theinput interface 270 may be configured with a touch screen, and an inputregion that accepts an operation input from the user may be displayed ona portion of the display 260 so that a touch operation input by the usercan be accepted.

Next, the control performed by the earphone controller 120 when the useradjusts the position of the biological sensor 111 is described in detailbelow. FIG. 4 is a flowchart illustrating one example of a processperformed by the earphone controller 120 illustrated in FIG. 1 when itadjusts the position. When the user measures the biological informationby using the earphone 100 according to this embodiment, he/she adjuststhe position of the biological sensor 111 beforehand. When the useradjusts the position, he/she performs a predetermined input to the inputinterface 270 of the mobile telephone 200, for example, to allow theearphone controller 120 to start the flow illustrated in FIG. 4.

First, the earphone controller 120 obtains the pulse wave data by usingthe biological sensor 111 (step S101). In particular, the earphonecontroller 120 obtains the pulse wave data by allowing the biologicalsensor 111 to irradiate the measuring light to the region to be testedand receive the reflected light from the region to be tested. At thistime, the intensity of the measuring light to be irradiated is anyintensity that allows the earphone controller 120 to determine whetherthe position of the biological sensor 111 should be changed or not. Theintensity of this measuring light may be constant and may not changeeach time the flow in FIG. 4 is executed.

The earphone controller 120 determines whether or not the obtained pulsewave data is within the allowable range that can be used for measurementof the biological information (step S102).

Here, the method performed by the earphone controller 120 to determinewhether or not the pulse wave data is within the allowable range isdescribed in detail. The earphone controller 120 determines whether ornot the obtained pulse wave data is within the allowable range accordingto the threshold relating to the allowable range stored in the storage130. The threshold relating to the allowable range is, for example, athreshold relating to the number of peaks in a predetermined period oftime, for example, and the earphone controller 120 determines whether ornot the pulse wave data is within the allowable range based on whetheror not the number of peaks of the pulse wave data is within the range ofthe threshold.

FIG. 5A and FIG. 5B are a diagram illustrating an example of the pulsewave data obtained by the biological sensor 111 illustrated in FIG. 1.When comparing FIG. 5A and FIG. 5B, the number of peaks of the pulsewave data in FIG. 5A is greater than that of the pulse wave data in FIG.5B. For example, when the number of peaks of the pulse wave data in FIG.5A is out of the range of the threshold stored in the storage 130, theearphone controller 120 determines that the pulse wave data includes alot of noise and the pulse wave data is not within the allowable range.On the other hand, when the number of peaks of the pulse wave data inFIG. 5B is within the range of the threshold stored in the storage 130,for example, the earphone controller 120 determines that the pulse wavedata is within the allowable range.

It should be noted that the threshold relating to the allowable range isnot limited to this example. The threshold relating to the allowablerange can be any threshold that allows the earphone controller 120 todetermine whether or not the pulse wave data is within the allowablerange. For example, the threshold can be those relating to variation inthe heights of peaks of the pulse wave data. The variation in theheights of peaks is defined by the standard deviation, for example. Inthis case, when the standard deviation of the height of peak is largerthan the predetermined threshold, the earphone controller 120 determinesthat the pulse wave data has a lot of noise and the pulse wave data isnot within the allowable range. On the other hand, in the case where thevariation in the heights of peaks is smaller than the predeterminedthreshold, the earphone controller 120 determines that the pulse wavedata is within the allowable range.

With reference to FIG. 4 again, in step S102, when the earphonecontroller 120 determines that the obtained pulse wave data is notwithin the allowable range (No in step S102), it displays an instructionto the user indicating that the position of the biological sensor 111 isneeded to be changed (step S103). The earphone controller 120 can allowthe notification unit 150 to notify the instruction indicating that theposition of the biological sensor 111 is needed to be changed, forexample. The earphone controller 120 can allow the display 260 of themobile telephone 200 to display the instruction indicating that theposition of the biological sensor 111 is needed to be changed, forexample. Based on the instruction to change the position, the userchanges the position of the biological sensor 111 by turning the turnadjusting part 117.

The earphone controller 120 uses the biological sensor 111 and obtainsthe pulse wave data again (step S101). At this time, the position of thebiological sensor 111 has been changed based on the instruction of theearphone controller 120 in step S103, thus the region to be tested fromwhich the biological sensor 111 obtains the pulse wave data has beenchanged. Since the pulse wave data varies depending on the positionalrelationship between the region to be tested and the biological sensor111, it is assumed that the pulse wave data to be obtained by theearphone controller 120 is different from the pulse wave data that hasbeen obtained earlier.

The earphone controller 120 determines whether or not the newly obtainedpulse wave data is within the allowable range that can be used formeasurement of the biological information (step S102).

When the earphone controller 120 determines that the obtained pulse wavedata is not within the allowable range (No in step S102), it displays aninstruction indicating that the position of the biological sensor 111 isneeded to be changed again to the user (step S103). In this manner, theearphone controller 120 repeats steps S101 to S103 until it determinesthat the obtained pulse wave data is within the allowable range.

When the earphone controller 120 determines that the obtained pulse wavedata is within the allowable range (Yes in step S102), it adjusts themeasured intensity of the biometry information in the biological sensor111 (step S104). For example, the earphone controller 120 adjusts theintensity of the measuring light outputted from the light-emittingelement of the biological sensor 111. As a result of this, the earphonecontroller 120 can adjust the light receiving intensity of the reflectedlight in the pulse wave data obtained by the biological sensor 111 tothe intensity suitable for measurement of the biological information. Inthis manner, the earphone controller 120 finishes control for adjustingthe position of the biological sensor 111. After adjusting the positionof the biological sensor 111, the user can measure the biologicalinformation.

It should be noted that, once adjusting the position of the biologicalsensor 111, for example, the user can repeatedly measure the biologicalinformation without adjusting the position again unless there is achange in the position of the biological sensor 111 in the insertionpart 110, for example.

As explained above, in the earphone 100, the position of the biologicalsensor 111 is adjusted before the biological information of the user ismeasured. Since the biometric output obtained by the biological sensor111 varies depending on the positional relationship between thebiological sensor 111 and the region to be tested, in the earphone 100,the biological sensor 111 can be disposed on a position where thebiological information can be measured with a high accuracy by adjustingthe position before measuring the biological information. Thus,according to the earphone 100, the measurement accuracy of thebiological information can be improved.

In the earphone 100, the user can change the position of the biologicalsensor 111 by pinching the turn adjusting part 117 with his/her fingersto turn it, and thus the user can adjust the position easily. Besides,even if the position of the biological sensor 111 is changed by the turnadjusting part 117, the ear canal connection 116 being in contact withthe ear canal of the user does not move in the ear canal of the user,and as a result, the wearing feeling of the earphone 100 does notchange.

As illustrated in FIG. 2, when the biological sensor 111 is disposed inthe sensor disposing part 112 that is different from the sound guidetube 113 and the sensor disposing part 112 is disposed on the outerperiphery side of the sound guide tube 113, the biological sensor 111 isless influenced by the vibration of the sound transmitted through thesound guide tube 113. That is, the biological sensor 111 is lessvibrated by the vibration of sound. As a result, the biological sensor111 can obtain the biometric output with a high accuracy.

It should be noted that this disclosure is not limited to the abovedescribed embodiment, and a variety of modifications or changes arepossible. For example, the functions or the like included in eachcomponent, step or the like may be reordered in any logically consistentmanner, and a plurality of components, steps or the like may be combinedinto one or divided.

For example, in the above described embodiment, the earphone controller120 performs a predetermined control when the user adjusts the positionof the biological sensor 111. However, the control is performed not onlyby the earphone controller 120. The control may be performed by themobile telephone controller 220, for example.

FIG. 6 is a functional block diagram of main parts of the measurementdevice in the case where the mobile telephone controller 220 performs apredetermined control when the position is adjusted. In this case, theearphone 100 includes the insertion part 110 having the biologicalsensor 111 and the communication interface 140 that connects to themobile telephone 200 wired or wirelessly to communicate with each other.The user operates the input interface 270 of the mobile telephone 200and starts the application for measurement of the biologicalinformation, for example, to measure the biological information by usingthe earphone 100. The biological sensor 111 obtains the pulse wave datain the same manner as that of the above described embodiment. Thecommunication interface 140 transmits the pulse wave data obtained bythe biological sensor 111 to the mobile telephone 200.

When adjusting the position of the biological sensor 111, the user usesthe position adjustment function of the above described application formeasurement of the biological information. When the mobile telephone 200obtains the pulse wave data from the earphone 100 via the communicationinterface 240, it performs a predetermined control to adjust theposition in the mobile telephone controller 220. For example, thepredetermined control is the control illustrated by the flow in FIG. 4.When performing the predetermined control, the mobile telephonecontroller 220 refers to the information relating to the allowable rangethat can be a criterion for determining whether the pulse wave data canbe used or not for measurement of the biological information. Theinformation relating to the allowable range is stored in the storage 230of the mobile telephone 200, for example. When the mobile telephonecontroller 220 instructs to change the position of the biological sensor111 in the step S103 in FIG. 4, it may instruct to change the positionby providing a notification from the notification part 250 of the mobiletelephone 200.

The user measures the biological information after the position of thebiological sensor 111 is adjusted by controlling the mobile telephonecontroller 220. In this case, the pulse wave data obtained by thebiological sensor 111 is transmitted from the earphone 100 to the mobiletelephone 200 via the communication interface 140. In the mobiletelephone 200, the mobile telephone controller 220 measures thebiological information based on the obtained pulse wave data. Themeasurement results are displayed on the display 260 of the mobiletelephone 200.

In the above described embodiment, although the insertion part 110 wasexplained as it includes the sensor disposing part 112 and the soundguide tube 113, the insertion part 110 is not limited to that describedin this embodiment. The insertion part 110 may have any structure if thebiological sensor 111 is configured to be turnable relative to the earcanal connection 116. For example, the insertion part 110 includes thesensor disposing part 112 in which the biological sensor 111 isdisposed, and the sensor disposing part 112 may serve as a sound guidetube that transmits sound. That is, in this case, unlike the abovedescribed embodiment, the insertion part 110 includes only onecylindrical member. As a result of this, the insertion part 110 can beconfigured in more simplified structure.

In the insertion part 110, as a mechanism to apply electrical signals tothe biological sensor 111 and the driving unit 115, a slip ring may beused.

1. A measurement device, comprising: a biosensor having alight-receiving part to receive measuring light from a region to betested and configured to obtain a biometric output based on themeasuring light; and a controller configured to determine whether or notto perform measurement of biological information based on the biometricoutput and a predetermined threshold.
 2. The measurement deviceaccording to claim 1, wherein the threshold is at least one of a firstthreshold according to a range of the number of peaks of the biometricoutput in a predetermined time and a second threshold according tovariation in a height of a peak.
 3. The measurement device according toclaim 2, wherein the controller performs measurement of the biologicalinformation at least one of when the biometric output is within a rangeof the first threshold and when the biometric output is smaller than thesecond threshold.
 4. The measurement device according to claim 2,wherein the controller does not perform measurement of the biologicalinformation at least one of when the biometric output is out of therange of the first threshold and when the biometric output is greaterthan the second threshold.
 5. The measurement device according to claim1, wherein, when performing measurement of the biological information,the controller adjusts an output intensity of the biometric output ofthe biosensor.
 6. The measurement device according to claim 5 furthercomprising: a light emitting part configured to output measuring lightto the region to be tested, wherein the controller adjusts an intensityof the measuring light output by the light emitting part to adjust theoutput intensity of the biometric output.
 7. The measurement deviceaccording to claim 1, wherein the controller allows a notification partto give a predetermined notification when performing no measurement ofthe biological information.
 8. The measurement device according to claim7, wherein the notification is given to notify that a positionadjustment of the biosensor is needed.
 9. The measurement deviceaccording to claim 1 further comprising: a position adjustment partconfigured to adjust a position of the biosensor with respect to theregion to be tested, wherein the position of the biosensor with respectto the region to be tested can be adjusted by the position adjustmentpart.
 10. The measurement device according to claim 1, wherein thebiometric output includes pulse wave data.
 11. A measurement method,comprising: obtaining a biometric output by a biosensor; anddetermining, by a controller, whether or not to perform measurement ofbiological information based on the biometric output and a predeterminedthreshold.
 12. The measurement method according to claim 11, wherein thethreshold is at least one of a first threshold according to a range ofthe number of peaks of the biometric output in a predetermined time anda second threshold according to variation in a height of a peak.
 13. Themeasurement method according to claim 12, further comprising:determining, by the controller, to perform measurement of the biologicalinformation at least one of when the biometric output is within a rangeof the first threshold and when the biometric output is smaller than thesecond threshold.
 14. The measurement method according to claim 12,further comprising: determining, by the controller, not to performmeasurement of the biological information at least one of when thebiometric output is out of the range of the first threshold and when thebiometric output is greater than the second threshold.
 15. Themeasurement method according claim 11, further comprising: adjusting, bythe controller, an output intensity of the biometric output of thebiosensor when measurement of the biological information is performed;and after adjusting, measuring the biological information.
 16. Themeasurement method according to claim 15, wherein the controller adjustsan intensity of measuring light output by a light emitting part toadjust an output intensity of the biometric output.
 17. The measurementmethod according to claim 11 further comprising: determining, by thecontroller, to give a predetermined notification when no measurement ofthe biological information is performed.
 18. The measurement methodaccording to claim 17, wherein the predetermined notification is givento notify that a position adjustment of the biosensor is needed.
 19. Themeasurement method according to claim 11, further comprising: disposingthe biosensor, by an ear canal connection configured to be inserted inan ear canal, into the ear canal; and after disposing, adjusting aposition of the biosensor with respect to a region to be tested.
 20. Themeasurement method according to claim 11, wherein the biometric outputis pulse wave data.